JP5111803B2 - Microcomputer meter - Google Patents

Description

  The present invention relates to a microcomputer meter that manages a gas usage state at a gas supply destination based on a detected gas flow rate, gas pressure, or the like.

  In recent years, a microcomputer meter mainly composed of a microcomputer is used at a gas supply destination, and a gas use state is managed based on a detected gas flow rate, gas pressure, or the like. As the number of abnormality determination programs required increases due to higher functionality of the microcomputer meter, the capacity of the microcomputer increases accordingly, which is one of the high cost factors of the microcomputer meter.

  In addition, new gas appliances such as gas dryers, gas heat pump air conditioners (GHP), and large gas appliances with proportional control functions are constantly being developed. Microcomputer meters are becoming more sophisticated.

  On the other hand, contrary to these demands for higher functionality, households using gas are diversifying due to the arrival of an aging society, and not all functions of microcomputer meters are necessary for small-volume households. The function is sufficient, and the current microcomputer meter is over-spec.

  In addition, since the functions of the microcomputer meter are unified and there is no room for the microcomputer capacity, it is difficult to meticulously deal with cold and warm area specifications, and it is also possible to provide specifications according to the country even for overseas markets. It was difficult. In addition, microcomputer meters are often used as they are for 10 years when installed due to the legal validity period of the law (measurement law), but should be managed in the meantime due to changes in family composition, owned equipment, and number of devices. Even if the function changes, the function of the micrometer cannot be changed correspondingly, and the micrometer itself needs to be replaced in order to respond. Therefore, there was a strong demand for making the microcomputer meter versatile and making it possible to respond individually and finely according to various usage situations.

  The present invention has been proposed in view of the above, and can accurately respond to various demands such as enhancement of functions and, on the other hand, only basic functions, and can respond individually and finely according to various usage situations. An object of the present invention is to provide a microcomputer meter that can reduce the manufacturing cost.

In order to achieve the above object, the invention described in claim 1 is a microcomputer meter that manages a gas usage state at a gas supply destination based on a detected gas flow rate, gas pressure, or the like. Various programs for managing usage states, storage means for storing parameter information used in the various programs, and new writing of programs and parameter information to the storage means in response to external access to the storage means, And an interface that enables rewriting and deletion of already written programs and parameter information, and the various programs and parameter information are prepared in advance in the external centralized monitoring center according to the gas type, and The gas type is based on the signal from the ultrasonic transducer provided in the gas flow path in the meter. The calculated sound velocity of the gas flowing in the gas flow path is identified and transmitted to the centralized monitoring center. The centralized monitoring center accesses the microcomputer meter and stores various programs and parameter information according to the gas type. write to the means, it is characterized a call.

  In the microcomputer meter of the present invention, various programs and parameter information are stored in the storage means, and new programs and parameter information are written to the storage means in response to external access, as well as programs and parameters already written. Since the information can be rewritten and deleted, it is possible to accurately respond to various requests such as enhancement of functionality and on the other hand only basic functions, and to respond individually and meticulously according to various usage situations. Can do. Furthermore, it is not necessary to provide a wide variety of microcomputer meters according to various demands, and therefore the manufacturing cost can be kept low.

  Microcomputer meters are manufactured with different specifications in terms of software depending on the type of gas, such as city gas and LP gas. For example, it is possible to rewrite a program or the like from a centralized monitoring center by accessing from a centralized monitoring center. For this reason, it is only necessary to provide the same microcomputer meter regardless of the gas type, and therefore the manufacturing cost can be kept low.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a block diagram schematically showing the configuration of the microcomputer meter of the present invention. In FIG. 1, the microcomputer meter 1 of the present invention is disposed in front of the gas supply destination 9 in the middle of the gas pipe 6, and manages the gas usage state at the gas supply destination 9 based on the detected gas flow rate and gas pressure. And a control unit 2, a pressure sensor 3, a flow rate sensor 4, and a shut-off valve 5.

  The microcomputer meter 1 is provided for each gas supply destination 9, and each microcomputer meter 1 is connected to the central monitoring center 7 via a telephone line or the like, and the control unit 2 makes a determination result such as occurrence of an abnormality. Then, the information is transmitted to the central monitoring center 7, and the central monitoring center 7 performs an appropriate response to the gas supply destination 9 based on the information.

  The control unit 2 is configured around a microcomputer, and estimates the gas usage state at the gas supply destination 9 based on the gas flow rate detected by the flow rate sensor 4, the gas pressure detected by the pressure sensor 3, and the like. It is determined whether or not the gas is properly used at the gas supply destination 9.

  The control unit 2 includes a storage unit 21 and operates according to various programs and parameters stored in the storage unit 21 to manage the gas use state.

  The storage means 21 stores various basic item management programs for managing the gas usage state, various high-function security programs other than the basic items, and parameter information used in these programs.

  This storage means 21 can perform new writing, rewriting, and deletion according to external access. That is, when there is an access from the centralized monitoring center 7 to the storage means 21 via a predetermined communication network 8, for example, the Internet, a new program or parameter information can be written to the storage means 21 via the interface 22 of the control unit 2. The program and parameter information already written in the storage means 21 can be rewritten and deleted.

  The flow sensor 4 is configured as an ultrasonic measurement unit in which a pair of ultrasonic transducers are arranged in the gas flow path, and based on a signal from the ultrasonic measurement unit, the flow rate of the gas flowing through the gas flow path and the gas flow A technique for calculating the speed of sound and specifying the type of gas from the gas flow rate and the speed of sound of gas is known (see Japanese Patent No. 3638252). In the present invention, by using an ultrasonic vibrator for the flow sensor 4, the microcomputer meter 1 has a gas type discrimination function, and the discriminated gas type (for example, city gas or LP gas) is sent to the centralized monitoring center 7. The centralized monitoring center 7 accesses the microcomputer meter 1 and writes various programs and parameters prepared in advance according to the gas type in the storage means 21 of the microcomputer meter 1 through the communication network. You can also

  In addition, the microcomputer meter 1 does not determine the gas type, but when the microcomputer meter 1 is installed, the operator notifies the central monitoring center 7 of the gas type to be used, and the central monitoring center 7 receives the notified gas. You may make it write a program etc. according to a classification.

  The microcomputer meter 1 is manufactured with different specifications in terms of software depending on the type of gas, such as city gas and LP gas. As described above, the program or the like can be rewritten from the centralized monitoring center 7 according to the gas type. For this reason, it is only necessary to provide the same microcomputer meter regardless of the gas type, and therefore the manufacturing cost can be kept low.

  FIG. 2 is a diagram showing a configuration example of the storage means. As described above, the storage means 21 stores various basic item programs, high-function security programs, and parameter information.

  For example, as shown in FIG. 2, the basic item program indicates the gas usage state such as the total flow rate monitoring program 21a, the increased flow rate monitoring program 21b, the usage time monitoring program 21c, the pressure drop monitoring program 21d, and the minute leakage monitoring program 21e. This program is basically required for monitoring.

  The total flow rate monitoring program 21a measures the total gas consumption amount of the combustion appliance at the installation destination, and when the set consumption amount is exceeded, it is determined that there is a large amount of gas leakage due to erroneous opening of the main plug, disconnection of the rubber hose, or the like. Based on this determination, the control unit 2 closes the shut-off valve 5 to shut off the gas.

  The increased flow rate monitoring program 21b determines that a large amount of gas leaks due to erroneous opening of the main plug, disconnection of the rubber hose, etc., when there is an abnormally large increase in gas flow rate compared to the maximum consumption device among the installed combustion devices. . Based on this determination, the control unit 2 closes the shut-off valve 5 to shut off the gas.

  If the usage time of the combustion appliance is abnormally long, the usage time monitoring program 21c determines that the gas leakage due to forgetting to turn off the combustion appliance or incomplete closing of the appliance plug. Based on this determination, the control unit 2 closes the shut-off valve 5 to shut off the gas.

  The pressure drop monitoring program 21d determines that the pressure has dropped when the gas pressure in the gas pipe 6 falls below a predetermined value based on the detection result of the pressure sensor 3. Based on this determination, the control unit 2 closes the shut-off valve 5 to shut off the gas.

The microleakage monitoring program 21e determines that the difference between the pressure immediately after gas stoppage (basic pressure) and the gas pressure measured every 15 minutes (monitoring pressure) exceeds the set threshold 20 mmH ₂ O. It is determined that there is a gas leak in the gas pipe 6 when there has been none over the number of days. Based on this determination, the control unit 2 displays a gas leak warning on the LCD display unit 11.

The high-function security program is, for example, a gas equipment determination program 21f, a CO ₂ prevention program 21g, and the like, and the parameter information is, for example, a pressure threshold Pa and a safety coefficient α.

  The gas device determination program 21f monitors the gas consumption pattern of the gas device used at the gas supply destination, and determines the type of the gas device, such as a gas instantaneous water heater, a gas fan heater, and a bathtub water heater. It is a program.

Further, the CO ₂ prevention program 21g determines that the gas continuation time of the gas instantaneous water heater is a predetermined time (for example, 20 minutes) if the gas equipment determined by the gas equipment determination program 21f is, for example, a small gas instantaneous water heater. If exceeded, it is determined that the indoor CO ₂ gas concentration may be high, and a warning is issued. Based on this warning, the controller 2 closes the shut-off valve 5 to shut off the gas.

The pressure threshold Pa (for example, 15 mmH ₂ O) is a parameter used in place of the set threshold 20 mmH ₂ O used in the minute leakage monitoring program 21e written in the storage unit 21. Since the gas pressure tends to decrease when the installation location of the microcomputer meter 1 is a cold region, the control unit 2 changes the set threshold value 20 mmH ₂ O in response to the pressure decrease and is written in the storage means 21. The minute leak monitoring program 21e is executed using the threshold value Pa.

  The safety coefficient α is a parameter used in place of the set consumption used in the total flow monitoring program 21a written in the storage unit 21. When the family structure at the time of installation of the microcomputer meter 1 is five and then changed to two, the gas consumption at the gas supply destination 9 decreases. Therefore, the control unit 2 executes the total flow monitoring program 21a using a smaller safety coefficient α written in the storage means 21 in order to reduce the set consumption (reference consumption x safety factor α). .

As described above, in the microcomputer meter 1 of the present invention, various programs and parameter information are stored in the storage means 21, and new programs and parameter information are written to the storage means 21 in response to external access. The written program and parameter information can be rewritten and deleted. Therefore, for example, in a household where the microcomputer meter 1 is desired to have a high function such as the CO ₂ prevention program 21g, it is possible to easily meet the demand without replacing the microcomputer meter 1 after installation. In addition, it is possible to write necessary programs and parameters according to whether the installation location is a cold region or a warm region, and the situation in various parts of the world. Moreover, even if the family structure changes after installation, it can respond appropriately. Moreover, in an aging household, a complicated and highly functional microcomputer meter is unnecessary, and only a basic function is satisfied, and it is possible to appropriately cope with such a situation.

  Furthermore, it is not necessary to provide a wide variety of microcomputer meters 1 according to various demands, and therefore the manufacturing cost can be kept low.

It is a block diagram which shows roughly the structure of the microcomputer meter of this invention. It is a figure which shows the structural example of a memory | storage means.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Microcomputer meter 2 Control part 3 Pressure sensor 4 Flow rate sensor 5 Shut-off valve 6 Gas piping 7 Centralized monitoring center 8 Communication network 9 Gas supply destination 11 Display part 21 Memory | storage means 21a Total flow rate monitoring program 21b Increased flow rate monitoring program 21c Usage time monitoring program 21d Pressure drop monitoring program 21e Micro leak monitoring program 21f Gas equipment determination program 21g Prevention program 22 Interface α Safety factor Pa Pressure threshold

Claims (1)

In a microcomputer meter that manages the gas usage at the gas supply destination based on the detected gas flow rate and gas pressure,
Various programs for managing the gas usage state at the gas supply destination, and storage means for storing parameter information used in the various programs,
An interface that enables new writing of programs and parameter information to the storage means, and rewriting and deletion of already written programs and parameter information in response to external access to the storage means;
Equipped with a,
The various programs are a total flow rate monitoring program, an increased flow rate monitoring program, a usage time monitoring program, a pressure drop monitoring program, a minute leakage monitoring program, a gas equipment determination program, and a CO ₂ prevention program.
The parameter information is a pressure threshold and a safety factor.
The various programs and parameter information are prepared in advance in the external centralized monitoring center according to the gas type,
The gas type is determined from the sound velocity of the gas flowing through the gas flow path, calculated based on the signal from the ultrasonic transducer provided in the gas flow path in the meter, and transmitted to the centralized monitoring center.
The centralized monitoring center accesses the microcomputer meter and writes various programs and parameter information according to the gas type in the storage means.
Microcomputer meter, wherein a call.

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